太阳周期活动对低高度内辐射带高能质子的影响
Effect of Solar Cycle Activity on High Energy Proton of Inner Radiation Belt in the Low Altitude Region
查看参考文献12篇
文摘
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利用NOAA - 15卫星1998年到2011年近13年的高能质子全向通量观测资料,分析了一个太阳活动周内,低高度内辐射带高能质子通量的分布变化特性及其物理原因,比较了观测结果与AP8模型的不同。研究表明,低高度内辐射带高能质子通量与太阳活动水平的反相关关系与磁壳参数L值及磁场B值有关;L值越低,B值越大的空间点,其高能质子通量与太阳活动水平的反向相关性越明显。高能质子通量随太阳活动水平的变化存在明显滞后现象,L值越高、B值越小的空间点,滞后现象就越明显,滞后严重时可以达到一年左右的时间;这种滞后现象反映出低高度内辐射带高能质子的源与损失达到平衡是一个中长期过程。通过与AP8模型计算结果的比较分析可以看出,利用AP8模型时,仅考虑地磁场长期变化对质子通量的影响可能会夸大低高度内辐射带局部高能质子通量的增强。 |
其他语种文摘
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The NOAA - 15 high energy proton observation from 1998 to 2011 is used to analyze the effect of solar cycle activity on high energy proton flux. The statistic research indicates that there is an inverse correlative relationship between the proton flux in inner radiation belt and solar activity. This anti-correlation is related to geomagnetic coordinates L and B, and more significant with the increasing of L and decreasing of B. There is also a phase lag between the solar activity and the proton flux. This hysteresis effect is more obvious in the region with smaller L or larger B. The lag can reach one year in some regions. This hysteresis effect means it takes a long time to reach the dynamic balance between the source and the loss for the proton of inner radiation belt in the low altitude region. The unbalance between the source and loss is the reason why the intensity of proton flux at the same solar activity is different. The comparison with the result of AP8 model indicates the energetic proton flux from AP8 is higher than the satellite's observation in the region with large B, which suggests that the AP8 model may overstate the proton flux enhancement at inner radiation belt in the low altitude region if only the long-term variation of magnetic field is considered. |
来源
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空间科学学报
,2012,32(6):804-811 【核心库】
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关键词
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高能质子
;
辐射带
;
太阳活动
;
南大西洋异常区
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地址
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1.
中国科学技术大学地球与空间科学学院, 合肥, 230026
2.
中国科学院空间科学与应用研究中心, 北京, 100190
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语种
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中文 |
ISSN
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0254-6124 |
学科
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地球物理学 |
基金
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国家973计划
;
中国科学院知识创新工程项目
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文献收藏号
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CSCD:4719442
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